Abstract
Facilitation is an important process during succession. Legumes often play a significant role as facilitators, particularly in primary succession, enriching the soil with nitrogen (N). The leguminous shrub Lupinus arboreus (Sims) can fix significant N on acidic, nutrient-poor soils. An apparent association between L. arboreus and Urtica dioica (L), which requires high concentrations of soil N and phosphorus (P), suggested that L. arboreus might facilitate colonisation by Urtica of nutrient-poor soils by increasing both soil N and P. I measured significantly higher concentrations of extractable soil P and higher values of soil pH beneath L. arboreus canopy, compared with areas between bushes, occupied by herbaceous vegetation. Litter inputs beneath L. arboreus were more than two and a half times higher in terms of mass of material and P and three times higher in terms of N, than in areas between bushes. This high litter input accounted for the higher soil P concentration and higher pH. It did not lead to higher soil organic matter content however, probably because high nutrient concentration in L. arboreus litter leads to rapid decay. A glasshouse trial showed that Urtica grew poorly on soil collected from areas between bushes of L. arboreus without the addition of supplementary N and P fertiliser, indicting co-limitation, by both N and P. Growth of Urtica on soil from beneath L. arboreus was more than four times higher than on soil from between L. arboreus. Amendment of the latter soil with N significantly increased growth of Urtica, but amendment with P did not, indicating that Urtica growth on this soil was not P limited, even when amended with N. Facilitation of colonisation of this site by Urtica therefore can be attributed to increased soil N and P, derived from litter of L. arboreus. However, in the field Urtica was only found beneath dead and senescent L. arboreus, suggesting a period of inhibition caused by shading, before senescence of L. arboreus allows light penetration to the nutrient-rich soil below.
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References
S.E. Allen (1989) Chemical Analysis of Ecological Materials Blackwell Scientific Publications Oxford, UK
P. Alpert H.A. Mooney (1996) ArticleTitleResource heterogeneity generated by shrubs and topography on coastal sand dunes Vegetatio 122 83–93 Occurrence Handle10.1007/BF00052818
J.D. Bolling L.R. Walker (2002) ArticleTitleFertile island development around perennial shrubs across a Mojave Desert chronosequence West. N. Am. Naturalist 62 88–100
A.D. Bradshaw W.S. Dancer J.F. Handley J.C. Sheldon (1975) The biology of land revegetation and the reclamation of the China clay wastes in Cornwall M.J. Chadwick G.T. Goodman (Eds) The Ecology of Resource Degradation and Renewal Blackwell Scientific Publications OxfordUK 363–384
R.M. Callaway (1995) ArticleTitlePositive interactions among plants Bot. Rev 61 306–349
J.L. Charley N.E. West (1975) ArticleTitlePlant induced soil chemical patterns in some shrub-dominated semi-desert ecosystems of Utah J. Ecol 63 945–963
F.S. Chapin L.R. Walker C.L. Fastie L.C. Sharman (1994) ArticleTitleMechanisms of primary succession following deglaciation at Glacier Bay, Alaska Ecol. Monogr 64 149–175
J.H. Connell R.O. Slayter (1977) ArticleTitleMechanisms of succession in natural communities and their role in community stability and organisation Am. Natur 111 1119–1144 Occurrence Handle10.1086/283241
J. Cortez (1998) ArticleTitleField decomposition of leaf litters: relationships between decomposition rates and soil moisturesoil temperature and earthworm activity Soil Biol. Biochem 30 783–793 Occurrence Handle10.1016/S0038-0717(97)00163-6
M.R. Davis (1991) ArticleTitleThe comparative phosphorus requirements of some temperate perennial legumes Plant Soil 133 17–30 Occurrence Handle10.1007/BF00011895
R. Del Moral L.C. Bliss (1993) ArticleTitleMechanisms of primary succession: insights resulting from the eruption of Mt St Helens Adv. Ecol. Res 24 1–66
S.J. Franks (2003) ArticleTitleFacilitation in multiple life-history stages: evidence for nucleated succession in coastal dunes Plant Ecol 168 1–11 Occurrence Handle10.1023/A:1024426608966
C.L. Fastie (1995) ArticleTitleCauses and ecosystem consequences of multiple pathways of primary succession at Glacier Bay, Alaska Ecology 76 1899–1916
R.L. Gadgil (1971) ArticleTitleThe nutritional role of L. arboreus in coastal sand dune forestry I. The potential influence of undamaged lupin plants on nitrogen uptake by Pinus radiata Plant Soil 34 357–367
R.J. Gosz G.E. Likens F.H. Borman (1973) ArticleTitleNutrient release from decomposing leaf and branch litter in the Hubbard Brook forestNew Hampshire Ecol. Monogr 43 173–191
J.P. Grime J.G. Hodgson R. Hunt (1988) Comparative Plant Ecology Unwin Hyman London
J.J. Halvorson J.L. Smith (1995) ArticleTitleDecomposition of lupine biomass by soil-microorganisms in developing Mount St-Helens pyroclastic soils Soil Biol. Biochem 27 983–992 Occurrence Handle10.1016/0038-0717(95)00026-B
G.M. Jacquez D.T. Patten (1996) ArticleTitle Chesneya nubigena on a Himalayan Glacial Moraine: A case of facilitation in primary succession? Mt. Res. Dev 16 265–273
N.B. Kramer F.D. Johnson (1987) ArticleTitleMature forest seed banks of three habitat types in central Idaho Can. J. Bot 65 1961–1966
E.J. Lammerts D.M. Pegtel A.P. Groontjans A. der Veen (1999) ArticleTitleNutrient limitation and vegetation changes in a coastal dune slack J. Veg. Sci 10 111–122
J.L. Maron P.G. Connors (1996) ArticleTitleA native nitrogen-fixing shrub facilitates weed invasion Oecologia 105 302–312 Occurrence Handle10.1007/BF00328732
J.L. Maron R.L. Jefferies (1999) ArticleTitleBush lupine mortality, altered resource availability, and alternative vegetation states Ecology 80 443–454
R.H. Marrs R.D. Roberts R.A. Skeffington A.D. Bradshaw (1981) ArticleTitleEcosystem development on naturally-colonized China clay wastes J. Ecol 69 163–169
J. Miles (1985) ArticleTitleThe pedogenic effects of different species and vegetation types and the implications of succession J. Soil Sci 36 571–584
R.J. Mitchell R.H. Marrs M.G. Le Duc M.H.D. Auld (1997) ArticleTitleA study of succession on lowland heaths in Dorsetsouthern England: Changes in vegetation and soil chemical properties J. Appl. Ecol 34 1426–1444
A.J. Moffat C.J. Roberts J.D. McNiell (1989) The Use of Nitrogen Fixing Plants in Forest Reclamation. Research Information note 158 Forestry Commission Research Division UK
A.J. Moffat C.J. Roberts (1989) ArticleTitleExperimental tree planting on China clay spoils in Cornwall Q. J. Forest 53 149–156
W.F. Morris D.M. Wood (1989) ArticleTitleThe role of lupine in succession on Mt St Helens: facilitation or inhibition? Ecology 70 697–703
P. Nørnberg L. Sloth K.E. Nielson (1993) ArticleTitleRapid changes of sandy soil caused by vegetation changes Can. J. Soil Sci 73 459–468
S.T.A. Pickett S.L. Collins J.J. Armesto (1987) ArticleTitleModels, mechanisms and pathways of succession Bot. Rev 53 335–371
C.D. Pigott (1971) ArticleTitleAnalysis of the response of Urtica dioica to phosphate New Phytol 70 953–966
F.I. Pugnaire P. Haase J. Puigdefabregas M. Cueto S.C. Clark L.D. Incoll (1996) ArticleTitleFacilitation and succession under the canopy of a leguminous shrubRetama sphaerocarpain a semi-arid environment in south-east Spain Oikos 76 455–464
R.D. Roberts R.H. Marrs R.A. Skeffington A.D. Bradshaw (1981) ArticleTitleEcosystem development on naturally colonised China clay wastes. I. Vegetation changes and overall accumulation of organic matter and nutrients J. Ecol 69 153–161
S.W. Shumway (2000) ArticleTitleFacilitative effects of a sand dune shrub on species growing beneath the shrub canopy Oecologia 124 138–148 Occurrence Handle10.1007/s004420050033
R.A. Skeffington A.D. Bradshaw (1980) ArticleTitleNitrogen fixation by plants grown on reclaimed China clay waste J. Appl. Ecol 17 469–477
P.J. Smethurst N.D. Turvey (1986) ArticleTitleEffect of Lupinus species on soil nutrient availability and the growth of Pinus radiata. Don. seedlings on a sandy podzol in VictoriaAustralia Plant Soil 95 183–190
J.I. Sprent W.B. Silvester (1973) ArticleTitleNitrogen fixation by Lupinus arboreus grown in the open and under different aged stands of Pinus radiata New Phytol 72 991–1003
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Gosling, P. Facilitation of Urtica dioica colonisation by Lupinus arboreus on a nutrient-poor mining spoil. Plant Ecol 178, 141–148 (2005). https://doi.org/10.1007/s11258-004-2782-2
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DOI: https://doi.org/10.1007/s11258-004-2782-2